Heat exchanger and integrated air-conditioning assembly including such exchanger

The invention claimed is: 1. An integrated assembly ( 100 ) for an air conditioning system ( 10 ) operating with a coolant including a heat exchanger ( 9 ), the heat exchanger ( 9 ) including a first tube ( 110 ) defining a path for the circulation of a fluid, in which the first tube ( 110 ) is wound in a spiral about an axis (A), called the axis of the heat exchanger ( 9 ), wherein the heat exchanger ( 9 ) also includes two second tubes ( 120 a , 120 b ) defining a path for the circulation of the fluid, in which the two second tubes ( 120 a , 120 b ) are fastened respectively to a face of the first tube ( 110 ) and wound in a spiral with the first tube ( 110 ) about the axis (A), wherein the two second tubes ( 120 a , 120 b ) are a second internal tube ( 120 a ) and a second external tube ( 120 b ), and wherein at each winding, an internal wall of the second internal tube ( 120 a ) is in contact with an external wall of the second external tube ( 120 b ), and including a main inlet tubing ( 111 ) is capable of receiving the fluid, a main outlet tubing ( 112 ) is capable of delivering the fluid to the outside of the heat exchanger, a secondary inlet tubing ( 121 ) is spaced radially from the first tube and the second tubes and the main inlet tubing and the main outlet tubing and extending axially from a first end to a second end for the fluid, parallel to the axis (A) of the heat exchanger ( 9 ) and a secondary outlet tubing ( 122 ) is spaced radially from the first tube and the second tubes and the main inlet tubing and the main outlet tubing and extending axially from a first end to a second end for the fluid, parallel to the axis (A) of the heat exchanger ( 9 ) to control circulation of the low-pressure fluid in the heat exchanger ( 9 ), in which the first end and second end of the first tube extends between the main inlet tubing and the main outlet tubing; a housing ( 130 ) having a lid ( 150 ) and a base ( 160 ) between which the heat exchanger ( 9 ) is housed, the lid ( 150 ) comprising a lower lid plate ( 150 b ) having a plurality of holes ( 151 a , 152 a , 153 a , 154 a ) on which the main outlet tubing ( 112 ), the secondary inlet tubing ( 121 ), the secondary outlet tubing ( 122 ), and the main inlet tubing ( 111 ) are brazed, and an upper lid plate ( 150 b ) having a plurality of holes aligned with the holes ( 151 a , 152 a , 153 a , 154 a ) of the lower lid plate ( 150 b ) and a plurality of pins ( 151 b , 152 b ) extending axially therefrom; a cap ( 170 ) having a plurality of first holes being capable of being attached on the pins ( 151 b , 152 b ) of the upper lid plate ( 150 b ) and having a plurality of second holes aligned with the holes in the upper lid plate ( 150 b ) to allow inlets/outlets of the high and low-pressure fluids of the heat exchanger ( 9 ) to be connected to corresponding external inlets/outlets of the air conditioning system ( 10 ); and a plurality of fasteners extending through the first holes of the cap ( 170 ) to attach the cap ( 170 ) to the pins ( 151 b , 152 b ). 2. The integrated assembly ( 100 ) according to claim 1 , in which at least one of the main inlet and outlet tubing ( 111 , 112 ) has a substantially cylindrical shape with an axis parallel to the axis (A) of the heat exchanger ( 9 ), and has an opening ( 113 , 114 ) capable of receiving an end of the first tube ( 110 ). 3. The integrated assembly ( 100 ) according to claim 1 , in which said first ( 110 ) and second ( 120 a , 120 b ) tubes are extruded. 4. The integrated assembly ( 100 ) according to claim 1 , in which the first ( 110 ) and second ( 120 a , 120 b ) tubes are fastened by brazing or bonding. 5. A method of operating the heat exchanger according to claim 1 as an internal heat exchanger ( 9 ) of an air conditioning system ( 10 ), characterized by passing the fluid through the first tube ( 110 ) as a high-pressure fluid, and passing the fluid through the second tube ( 120 a , 120 b ) as a low-pressure fluid. 6. The method of operating according to claim 5 , in which the high-pressure fluid and the low-pressure fluid comprise the same coolant. 7. The method of operating according to claim 6 , in which the coolant is a supercritical fluid. 8. The integrated assembly ( 100 ) according to claim 1 , in which the base ( 160 ) is equipped with an inlet ( 161 a , 161 b ) allowing the second fluid into the windings formed by the first ( 110 ) and second ( 120 a , 120 b ) tubes, and in that the housing ( 130 ) includes the secondary outlet tubing ( 122 ) and comprising an outlet opening ( 123 ). 9. The integrated assembly ( 100 ) according to claim 8 , comprising the secondary inlet tubing ( 121 ) of which one end communicates with the outlet ( 161 a , 161 b ) through the base ( 160 ). 10. The integrated assembly ( 100 ) according to claim 9 , comprising an accumulator ( 17 ) connected to the base ( 160 ), into which the secondary inlet tubing ( 121 ) leads so as to communicate with the outlet ( 161 a , 161 b ). 11. The integrated assembly ( 100 ) according to claim 8 , in which the housing ( 130 ) extends in the extension of the heat exchanger ( 9 ) after the base ( 160 ) and comprises a chamber for receiving the low-pressure fluid. 12. The integrated assembly ( 100 ) according to claim 8 , in which the main tubings ( 111 , 112 ) and the secondary tubings ( 121 , 122 ) are arranged for co-current circulation of the fluid in the first tube ( 110 ) with that of the fluid in the second tube ( 120 a , 120 b ). 13. The integrated assembly ( 100 ) according to claim 8 , in which the main tubings ( 111 , 112 ) and the secondary tubings ( 121 , 122 ) are arranged for counter-current circulation of the fluid in the first tube ( 110 ) with that of the fluid in the second tube ( 120 a , 120 b ). 14. An air conditioning system ( 10 ) operating with a coolant, including a compressor ( 14 ), a gas cooler ( 11 ), an expansion chamber ( 12 ), and an evaporator ( 13 ), characterized in that the air conditioning system ( 10 ) comprises the integrated assembly ( 100 ) according to claim 8 , in which the main inlet tubing ( 111 ) is connected to the gas cooler ( 11 ) and the main outlet tubing ( 112 ) is connected to the expansion chamber ( 12 ), while the secondary inlet tubing ( 121 ) is connected to the evaporator ( 13 ), and the secondary outlet tubing ( 122 ) is connected to the compressor ( 14 ).